CN112723753A

CN112723753A - Glazed tile glaze pouring production line

Info

Publication number: CN112723753A
Application number: CN202011569487.7A
Authority: CN
Inventors: 刘雨瑄; 崔强; 张俊; 张明胜; 刘俊
Original assignee: Zouping Hongyu Boying Building Materials Co ltd
Current assignee: Shandong Xinhongyu New Building Materials Co ltd
Priority date: 2020-12-26
Filing date: 2020-12-26
Publication date: 2021-04-30
Anticipated expiration: 2040-12-26
Also published as: CN112723753B

Abstract

The utility model relates to a glazed tiles waters glaze production line belongs to glazed tiles production facility's field, including a pair of conveying strip with transporting the tile, be used for in proper order towards the tile on the conveying strip water the first glaze platform and the glaze platform is watered to the second of watering and set up at the first turning device who waters between glaze platform and the second and be used for carrying out the change with the tile positive and negative. During operation, the staff places the tile on the conveying strip, tile on the conveying strip moves to the first glaze platform department of watering back, the first glaze platform of watering deviates from the surface of conveying strip towards the tile and waters and drench the frit, after the tile moves to turning device department back, turning device will be watered and place again on the conveying strip after the tile upset of drenching the frit, after the tile continues to water the glaze platform operation towards the second, treat that the tile moves when watering glaze platform position department to the second, the glaze is watered again to the tile to the second glaze platform, so that two tile surfaces of tile are all watered and have been drenched the frit. The production line is convenient to set up and glaze two tile surfaces of the tile, and labor intensity is reduced.

Description

Glazed tile glaze pouring production line

Technical Field

The application relates to the field of glazed tiles production facility, especially relate to a glazed tiles glaze casting production line.

Background

Glazed tiles often need water glaze to its tile when production, and among the correlation technique, glazed tiles waters the glaze production line and includes a pair of conveying strip of placing the tile, and conveying strip level sets up, and conveying strip is connected with its actuating mechanism of moving towards a direction of drive, and the top of conveying strip is provided with the glaze platform of watering that is used for watering the glaze. During operation, the staff places the tile on the conveying strip, and then the conveying strip moves the tile piece and moves to the below of watering the glaze platform, waters the glaze platform and waters the frit towards the tile on the conveying strip, and then the conveying strip moves the tile piece and passes and waters the glaze platform, and the staff takes off the conveying strip of watering the glaze on the conveying strip.

With respect to the related art among the above, the inventors consider that the following drawbacks exist: when the tile is processed by the production line, the production line can only pour glaze on one tile surface of the tile, and cannot pour glaze on two tile surfaces of the tile.

Disclosure of Invention

For the convenience of staff to water the glaze to two tile surfaces of tile, this application provides a glazed tiles waters glaze production line.

The application provides a glazed tile glaze pouring production line relates to following specific scheme:

the utility model provides a glazed tiles waters glaze production line, includes a pair of conveying strip with transporting the tile, be used for in proper order towards the tile on the conveying strip water the first glaze platform and the glaze platform is watered to the second of drenching the glaze and set up and water the turning device that is used for carrying out the change with the tile positive and negative between the glaze platform at first glaze platform and the second of watering.

Through adopting above-mentioned technical scheme, in operation, the staff places the tile on the conveying strip, the tile on the later conveying strip is towards the first glaze platform direction operation of watering, tile on the conveying strip moves to the first glaze platform department of watering after, the first glaze platform of watering deviates from the surface of conveying strip towards the tile and waters and drench the frit, the tile passes the first glaze platform of watering and moves to turning device department after, turning device will be watered and place again on the conveying strip after the tile upset 180 degrees of glaze, the conveying strip moves the tile and continues to water the glaze platform operation towards the second, treat that the tile moves when watering glaze platform position department to the second, the second waters the glaze platform and waters again and drenches the glaze to the tile, so that two tile surfaces of tile are all watered and have the glaze. The glazed tile glaze pouring production line is convenient for workers to pour glaze on two tile surfaces of the tile, and labor intensity of the workers is reduced.

Optionally, the turnover device comprises a clamping assembly used for clamping two ends of the tile, a lifting assembly used for controlling the clamping assembly to ascend or descend, and a rotating assembly used for controlling the clamping assembly to drive the tile to overturn, wherein the clamping assembly comprises a clamping cylinder, a supporting rod and a supporting stand column, the clamping cylinder and the supporting stand column are symmetrically arranged at two ends of the tile, the supporting stand column is horizontally arranged, a piston rod of the supporting stand column is arranged towards the end portion of the tile and fixedly connected with the supporting rod, the supporting stand column is vertically arranged, one end of the supporting stand column is connected with the lifting assembly, the other end of the supporting stand column is connected with a cylinder body of the clamping cylinder in a rotating.

Through adopting above-mentioned technical scheme, when the tile on the pending strip that conveys moves to between two die clamping cylinder, die clamping cylinder's piston rod extension, so that support the both ends of tight pole support tile, later lifting unit control die clamping cylinder and tile shift up, so that the tile breaks away from the conveying strip, later runner assembly control tile overturns 180 degrees, the back that finishes overturns, lifting unit control die clamping cylinder and tile move down, so that the tile is connected with the conveying strip, die clamping cylinder's piston rod shrink simultaneously, so that the tile can continue to water glaze platform department operation towards the second along the conveying strip. The setting of die clamping cylinder can control the tight tile of tight pole clamp in a flexible way, and the tight pole of support can make the tile tightly by tight firmly.

Optionally, the lifting assembly comprises a lifting hydraulic cylinder and a supporting cross rod, the supporting cross rod is horizontally arranged below the conveying strip, the lifting hydraulic cylinder is vertically arranged, a piston rod of the lifting hydraulic cylinder is fixedly connected with the supporting cross rod, and the supporting upright post is fixedly connected with the supporting cross rod.

Through adopting above-mentioned technical scheme, hydraulic cylinder's piston rod extension, steerable support horizontal pole moves up, and then makes support post and die clamping cylinder shift up to drive the tile and break away from the conveying strip and shift up. The piston of the lifting hydraulic cylinder contracts to control the supporting cross rod to move downwards, so that the supporting upright posts and the clamping cylinder move downwards to drive the tiles to move downwards and be connected with the conveying strips. The tile can be controlled by the lifting hydraulic cylinder to ascend or descend, and the lifting hydraulic cylinder is stable in performance and convenient to control.

It is optional, the runner assembly is provided with a pair ofly, and is located the both ends of tile respectively, the runner assembly includes slide rail post, rotating gear and lifting rack, the vertical setting of slide rail post has seted up the spout along its length direction, the lifting rack slides in the spout along vertical direction, rotating gear is connected with lifting rack meshing, rotating gear coaxial key fixedly connected with pivot, pivot one end pass the support post and with die clamping cylinder's cylinder body fixed connection, be provided with the friction disc that is used for increasing frictional force between the two between pivot and the support post, slide rail post lower extreme and base face fixed connection, the upper end is connected with the piece of support that is used for supporting lifting rack and shifts up.

By adopting the technical scheme, after the tile is clamped by the clamping rod, the piston rod of the lifting hydraulic cylinder stretches, and the supporting upright posts drive the tile and the rotating shaft to move upwards. Because the friction disc makes the frictional force between pivot and the support post great, and then makes the not easy emergence rotation of rotating gear, when the lifting rack was not connected with the piece that supports tightly, the piston rod extension of hydraulic cylinder can make the rotating gear drive the lifting rack and shift up together. After the upper end of the lifting rack is connected with the abutting part, the abutting part abuts against the end part of the lifting rack, then a piston rod of the lifting hydraulic cylinder continues to extend, the rotating gear rotates under the action of the lifting rack, after the rotating gear rotates forwards for 180 degrees, the piston rod of the lifting hydraulic cylinder contracts to enable the tile to be connected with the conveying strip, then the piston rod of the clamping cylinder contracts, the tile is placed on the conveying strip, then the piston rod of the lifting hydraulic cylinder continues to contract, the lower end of the lifting rack abuts against the side wall of the sliding groove, and after the transmission gear rotates reversely for 180 degrees, the piston rod of the lifting hydraulic cylinder stops running.

Optionally, the sliding rail column is provided with a sliding slot along a length direction thereof, the fastening piece comprises a plug board inserted in the sliding slot in a sliding manner and a fastening board fixedly connected with the upper end of the plug board, the fastening board is located above the sliding slot and the sliding groove, and the plug board is connected with a fixing piece for fixing the position of the fastening board located in the sliding slot.

Through adopting above-mentioned technical scheme, fix the plugboard inside the sliding slot, support tight board and be located the top of spout and sliding slot, wait that the lifting rack rises to remove to with support tight board contact back, support tight board its position height under the effect of plugboard and fix, and then can support tight lifting rack to make lifting rack can't continue to move up, later the running gear continues to rise alright rotate.

Optionally, the fixing member is a fixing bolt, the fixing bolt is in threaded connection with the side wall of the sliding slot, and one end of the fixing bolt penetrates through the inside of the sliding slot and abuts against the insertion plate.

Through adopting above-mentioned technical scheme, through unscrewing fixing bolt, adjustable plugboard is being located the inside position of slip slot, and then changes the interval of holding between board and the spout upper end opening to make turning device adaptable not unidimensional tile, and then improve turning device's adaptability.

Optionally, the turnover device further comprises a micro-drying assembly for pre-drying the tiles, the micro-drying assembly comprises an oven shell, a heating wire arranged inside the oven shell, and supporting legs for supporting the oven shell, the oven shell is sleeved on the outer side of the conveying strip, and the oven shell is located between the lifting assembly and the first glazing table.

Through adopting above-mentioned technical scheme, the tile is crossed and is watered and drench and have had the frit after first watering the glaze platform, and later the tile continues to move to inside the oven casing along conveying the strip, and inside the oven casing has higher temperature, can play certain stoving effect to the frit on the tile for frit on the tile is difficult to flow when the upset.

Optionally, the first glaze pouring table and the second glaze pouring table are identical in structure, the first glaze pouring table comprises a glaze pouring frame and a glaze supply assembly, the glaze pouring frame is connected with a spray nozzle used for spraying glaze towards the tile in a reciprocating sliding mode along the direction perpendicular to the conveying strip, the spray nozzle is located above the tile, one end of the spray nozzle is arranged towards the tile, the other end of the spray nozzle is connected with the glaze supply assembly, and the spray nozzle is connected with a driving assembly used for driving the spray nozzle to reciprocate.

Through adopting above-mentioned technical scheme, when watering glaze, the staff puts the tile to the conveying strip on, and later conveying strip operation drives the tile and removes towards first glaze pouring platform department of watering, on later spraying the mouth and spraying glaze to the tile, drive assembly control simultaneously sprays the mouth along the reciprocal operation of the length side of perpendicular to conveying strip to make the glaze on the tile even.

Optionally, the glaze supply assembly comprises a glaze supply hose, a glaze supply pump and a glaze barrel for storing glaze, one end of the glaze supply hose is connected with the spray nozzle, the other end of the glaze supply hose is connected with the glaze arch pump, the glaze supply pump is placed in the glaze barrel, the glaze pouring frame is fixedly connected with a support slide bar, the support slide bar is horizontally arranged and perpendicular to the conveying bar, the driving assembly comprises a rotary disc, a push rod and a slide rod which is slidably connected with the support slide bar, the slide rod is slidably arranged on the support slide bar along the length direction of the support slide bar, the spray nozzle is fixedly connected with the slide rod, the surface of the rotary disc is vertically arranged, the rotary disc and the glaze pouring frame are rotatably arranged, the side wall of the rotary disc is fixedly connected with a connecting rod, the connecting rod is arranged parallel to the disc surface of the rotary disc along the length direction of the rotary disc, the extending line of the connecting rod along the length direction of, the other end is hinged with the sliding rod, and the rotary table is connected with a power assembly for driving the rotary table to rotate.

Through adopting above-mentioned technical scheme, the frit is placed in the glaze bucket, when waiting to water the glaze, supplies the glaze pump to start to extract the frit in the glaze bucket, the frit sprays to the tile through spraying the mouth behind supplying the glaze hose on, waters the glaze to the tile. The carousel rotates, and the carousel passes through the connecting rod and drives the catch bar operation, and the catch bar promotes the slide bar along the length direction reciprocating motion of supporting the slide bar, and then drives and spray the mouth and remove to water the glaze to the tile.

Optionally, power component includes motor power and connection belt, and the carousel deviates from the coaxial fixedly connected with connecting axle of face of connecting rod, the connecting axle rotates with watering the glaze frame and is connected, the coaxial fixed cover of connecting axle is equipped with the rotation band pulley, motor power with water glaze frame fixed connection, and motor power's output shaft coaxial key fixedly connected with driving pulley, the connection belt cover is established on rotation band pulley and driving pulley.

Through adopting above-mentioned technical scheme, power motor rotates and rotates in order to drive the driving pulley, and then connects the belt and drive the rotation band pulley and rotate with the carousel, and the carousel rotates to make the connecting rod can drive catch bar drive slide bar along the length direction reciprocating motion of supporting the slide bar, and then make the nozzle operation of spraying in order to water the glaze to the tile.

In summary, the present application includes at least one of the following advantageous technical effects:

1. the glazed tile glaze casting production line is arranged as follows: during operation, the staff places the tile on the conveying strip, the tile on the later conveying strip is towards the first glaze platform direction of watering operation, the tile on the conveying strip moves to the first glaze platform department of watering back, the first glaze platform of watering deviates from the surface of conveying strip towards the tile and waters the frit, the tile passes the first glaze platform of watering and moves to turning device department after, turning device will be watered and place again on the conveying strip after the tile upset 180 degrees of glaze, the conveying strip moves the tile piece and continues to water the glaze platform operation towards the second, treat that the tile moves to the second and water glaze platform position department when, the second waters the glaze platform and waters the frit once more to the tile, so that two tile surfaces of tile are all watered and are drenched the glaze. The glazed tiles are watered setting up of glaze production line and have made things convenient for the staff to water the glaze to two tile surfaces of tile, improve glazed tiles's water-proof effects, reduced staff's intensity of labour simultaneously.

2. The setting of lifting unit and runner assembly: after the tile is clamped by the clamping rod, a piston rod of the lifting hydraulic cylinder stretches, and the supporting upright posts drive the tile and the rotating shaft to move upwards. Because the friction disc makes the frictional force between pivot and the support post great, and then makes the not easy emergence rotation of rotating gear, when the lifting rack was not connected with the piece that supports tightly, the piston rod extension of hydraulic cylinder can make the rotating gear drive the lifting rack and shift up together. After the upper end of the lifting rack is connected with the abutting part, the abutting part abuts against the end part of the lifting rack, then a piston rod of the lifting hydraulic cylinder continues to extend, the rotating gear rotates under the action of the lifting rack, after the rotating gear rotates forwards for 180 degrees, the piston rod of the lifting hydraulic cylinder contracts to enable the tile to be connected with the conveying strip, then the piston rod of the clamping cylinder contracts, the tile is placed on the conveying strip, then the piston rod of the lifting hydraulic cylinder continues to contract, the lower end of the lifting rack abuts against the side wall of the sliding groove, and after the transmission gear rotates reversely for 180 degrees, the piston rod of the lifting hydraulic cylinder stops running.

Drawings

FIG. 1 is a schematic diagram of the overall structure of an embodiment of the present application;

FIG. 2 is a schematic view of the overall structure of the first or second glazing table according to an embodiment of the present application;

FIG. 3 is a schematic structural diagram of a turning device according to an embodiment of the present application;

FIG. 4 is an enlarged schematic view of portion A of FIG. 3;

fig. 5 is a schematic half-sectional view of a micro-baking assembly according to an embodiment of the present disclosure.

Description of reference numerals: 100. a transfer bar; 200. a first glazing table; 2100. a second glazing table; 210. a glaze pouring frame; 220. a spray nozzle; 230. a glaze supply assembly; 231. a glaze supply hose; 232. a glaze supply pump; 233. a glaze barrel; 240. supporting the sliding rod; 250. a slide bar; 269. a turntable; 270. a connecting rod; 271. a push rod; 280. a power assembly; 281. a power motor; 282. connecting a belt; 283. a connecting shaft; 284. a drive pulley; 285. rotating the belt pulley; 300. a clamping assembly; 310. a clamping cylinder; 320. a tightening rod; 400. a lifting assembly; 410. supporting the upright post; 420. a lifting hydraulic cylinder; 430. a support rail; 500. a rotating assembly; 510. a slide rail column; 511. a chute; 512. a sliding slot; 520. a rotating gear; 530. a lifting rack; 540. a rotating shaft; 550. a friction plate; 560. a propping plate; 570. a plugboard; 600. a micro-baking assembly; 610. a baking oven housing; 620. an electric heating wire; 630. and (5) supporting legs.

Detailed Description

The present application is described in further detail below with reference to figures 1-5.

The embodiment of the application discloses glazed tiles waters glaze production line.

The utility model provides a glazed tiles glaze pouring production line, refers to figure 1, includes a pair of conveying strip 100 with transporting the tile, two are used for watering the glaze platform of drenching the frit for the tile and set up and water the turning device that the glaze platform was used for changing the tile positive and negative between two. The two glazing tables are the same in mechanism, the two glazing tables are respectively a first glazing table 200 and a second glazing table 2100, tiles on the conveying strip 100 are glazed through the first glazing table 200, and then the tiles are moved to the second glazing table 2100 for glazing.

Referring to fig. 1 and 2, the first glazing station 200 includes a glazing frame 210 and a glaze supply assembly 230. The glazing frame 210 is disposed on one side of the conveyor strip 100, and the glazing frame 210 is fixedly disposed on a base surface, which is the base surface in this embodiment. The glaze pouring frame 210 is connected with a spraying nozzle 220 used for spraying glaze towards the tiles in a reciprocating sliding mode along the direction perpendicular to the running direction of the conveying strip 100, the spraying nozzle 220 is located above the tiles, one end of the spraying nozzle 220 faces the tiles, the other end of the spraying nozzle is connected with a glaze supply assembly 230, and the spraying nozzle 220 is connected with a driving assembly driving the spraying nozzle to reciprocate.

The glaze supplying assembly 230 includes a glaze supplying hose 231, a glaze supplying pump 232, and a glaze bucket 233 for storing glaze. One end of the glaze supply hose 231 is connected with the spray nozzle 220, the other end is connected with the glaze arching pump 232, the glaze supply pump 232 is placed in the glaze barrel 233, and glaze is filled in the glaze barrel 233. During operation, supply glaze pump 232 to start, in glaze hose 231 is supplied to glaze material flow through supplying glaze pump 232, later on water from spraying nozzle 220 and drench on the tile. The glaze pouring frame 210 is fixedly connected with two supporting slide bars 240, the central axes of the two supporting slide bars 240 are parallel to each other and are positioned on the same horizontal plane, and the supporting slide bars 240 are arranged perpendicular to the conveying strip 100. The driving assembly includes a turntable 269, a push rod 271, and a slide rod 250 slidably coupled with the support slide rod 240. The turntable 269 is disc-shaped, two ends of the sliding rod 250 are slidably sleeved on the two supporting sliding rods 240, and the spraying nozzle 220 is fixedly connected with the sliding rod 250. The conveying strip 100 is horizontally arranged, the plate surface of the rotating disc 269 is perpendicular to the conveying strip 100, the rotating disc 269 is rotatably connected with the glaze pouring frame 210, the connecting rod 270 is fixedly connected to the side wall of the rotating disc 269, the connecting rod 270 is parallel to the disc surface of the rotating disc 269 along the length direction of the connecting rod 270, and the extension lines of the connecting rod 270 and the connecting rod 270 do not pass through the central axis of the rotating disc 269. The push rod 271 is perpendicular to the length direction of the conveying strip 100, and one end of the push rod 270 is hinged to the connecting rod 270, and the other end is hinged to the sliding rod 250. The turntable 269 is coupled to a power assembly 280 for driving rotation thereof.

The power assembly 280 includes a power motor 281 for providing a power source for rotation of the turntable 269 and a connecting belt 282 for connecting the power motor 281 to the turntable 269. A connecting shaft 283 is fixedly connected to the disk surface of the turntable 269 along the central axis direction thereof. One end of the connecting shaft 283 is fixedly welded with the side wall of the turntable 269 departing from the connecting rod 270, the other end of the connecting shaft 283 is rotatably connected with the glaze pouring frame 210, and the connecting shaft 283 is coaxially and fixedly sleeved with a rotating belt wheel 285. The power motor 281 is connected with the glaze pouring frame 210 through a connecting bolt, an output shaft of the power motor 281 is fixedly connected with a driving belt wheel 284 through a coaxial key, and a connecting belt 282 is sleeved on the rotating belt wheel 285 and the driving belt wheel 284. During operation, power motor 281 rotates, and then drives and connect belt 282 and rotate to make carousel 269 rotate, rotate carousel 269 accessible connecting rod 270 and catch bar 271 and drive slide bar 250 along the reciprocating motion of the length side that supports slide bar 240, so that it is even to water and drench the frit.

Referring to fig. 1 and 3, the turnover device includes a clamping assembly 300 for clamping tiles, a lifting assembly 400 for controlling the clamping assembly 300 and the tiles to ascend or descend, and a rotating assembly 500 connected to the clamping assembly 300 for controlling the tiles to turn 180 degrees. The clamping assembly 300 includes clamping cylinders 310 symmetrically disposed at both ends of the tile, a tightening rod 320, and a support pillar 410 for supporting the clamping cylinders 310. The power source of the air cylinder 310 is provided by an air pump, the air cylinder 310 is horizontally and vertically arranged along the length direction of the conveying strip 100, and the piston rod of the air cylinder 310 is arranged opposite and towards the end of the tile. The tightening rod 320 is disposed parallel to the conveying strip 100, and the tightening rod 320 is fixedly connected to the piston rod of the clamping cylinder 310. The support column 410 is vertically disposed and has one end connected to the lifting assembly 400 and the other end rotatably disposed with the clamping cylinder 310. The rotating assembly 500 is connected to the cylinder body of the clamping cylinder 310 to control the clamping cylinder 310 to rotate.

The lift assembly 400 includes a lift cylinder 420, a support rail 430. The power source of the lifting hydraulic cylinder 420 is provided by a hydraulic pump, the lifting hydraulic cylinder 420 is vertically arranged, the cylinder body of the lifting hydraulic cylinder is fixedly arranged on the base surface, and the piston rod of the lifting hydraulic cylinder is positioned below the conveying strip 100 and is arranged towards the conveying strip 100. The support cross bar 430 is horizontally disposed below the conveying strip 100, and is fixedly welded to the piston of the lifting hydraulic cylinder 420, and the lower end of the support column 410 is fixedly welded to the support cross bar 430. The piston rod of the hydraulic lift cylinder 420 is extended to move the support column 410, the clamp cylinder 310 and the tile upward. Retraction of the piston rod of the hydraulic lift cylinder 420 controls downward movement of the support column 410, the clamp cylinder 310 and the tile.

Referring to fig. 3 and 4, the rotating assembly 500 is provided in a pair and is located at both ends of the tile, respectively. The rotating assembly 500 includes a sliding rail post 510, a rotating gear 520, and a lifting rack 530. The slide rail column 510 is vertically arranged, the lower end thereof is fixedly arranged on the base surface, and the upper end thereof is provided with a slide groove 511 along the length direction thereof. The lifting rack 530 is vertically disposed, and the lifting rack 530 slides in the sliding slot 511 in a vertical direction. The rotating gear 520 is meshed with the lifting rack 530, the rotating shaft 540 is fixedly welded to the rotating gear 520 through a coaxial key, the rotating shaft 540 is welded to the cylinder body of the clamping cylinder 310, and a friction plate 550 used for increasing friction force between the clamping cylinder 310 and the supporting upright column 410 is arranged between the clamping cylinder 310 and the supporting upright column 410. The upper end of the sliding rail column 510 is connected with a propping member for propping the lifting rack 530 to move upwards excessively. The abutting piece comprises an abutting plate 560 and a plug plate 570, the abutting plate 560 and the plug plate 570 are integrally formed, and the abutting plate 560 is perpendicular to the plug plate 570. The sliding rail column 510 is provided with a sliding slot 512 along the length direction thereof, the insertion plate 570 is inserted into the sliding slot 512 in a sliding manner along the vertical direction, and the abutting plate 560 is positioned above the sliding slot 512 and the sliding slot 511. The insertion plate 570 is connected with a fixing member for fixing the position thereof inside the sliding insertion groove 512. The fixing member is a fixing bolt, the fixing bolt is in threaded connection with the side wall of the sliding slot 512, and one end of the fixing bolt penetrates through the inside of the sliding slot 512 and abuts against the insertion plate 570.

Referring to fig. 1 and 5, the turning apparatus further includes a micro-baking assembly 600 between the lifting assembly 400 and the first glazing stand 200. The micro-bake assembly 600 includes an oven housing 610, heating wires 620, and a plurality of support legs 630. The oven housing 610 is sleeved outside the conveying strip 100, and the heating wire 620 is positioned above the conveying strip 100 and the tiles. When the heating wire 620 works, the temperature in the oven shell 610 rises, and the tile runs to the inside of the oven shell 610 after passing through the first glaze pouring table 200, so that the glaze on the tile is preliminarily dried, and the glaze is firmly adhered to the tile.

The implementation principle of the embodiment of the application is as follows: the worker places the tiles on the conveying strip 100, then the tiles move to the lower part of the first glazing table 200 along the conveying strip 100, the glaze pump 232 works to supply glaze materials in the glaze supply hose 231, the glaze materials are sprayed on the tiles through the spraying nozzle 220, meanwhile, the power motor 281 rotates to drive the turntable 269 to rotate through the connecting belt 282, the turntable 269 rotates to enable the connecting rod 270 and the pushing rod 271 to drive the sliding rod 250 to reciprocate along the length direction of the supporting sliding rod 240, then the tiles move to the inside of the oven shell 610 along the conveying strip 100 to be heated, when the tiles move between the two clamping cylinders 310, the piston rods of the clamping cylinders 310 extend to enable the abutting rods 320 to abut against the tiles, then the piston rods of the lifting hydraulic cylinders 420 extend to enable the tiles to be separated from the conveying strip 100, the lifting rack 530 continues to move upwards along the length direction of the sliding rail column 510, after the end parts of the lifting rack 530 abut against the abutting plates 560, the piston rod of the lifting hydraulic cylinder 420 continues to extend, the rotating gear 520 rotates to drive the rotating shaft 540 to rotate forwards for 180 degrees in the axial direction, then the piston rod of the lifting cylinder contracts, the lifting rack 530 moves downwards, after the tiles fall onto the conveying strip 100, the piston rod of the clamping cylinder 310 contracts, the abutting rod 320 is separated from the tiles, then the piston rod of the lifting hydraulic cylinder 420 continues to contract, the lower end of the lifting rack 530 abuts against the bottom wall of the sliding groove 511, the rotating gear 520 rotates, and the rotating shaft 540 rotates in the reverse direction for 180 degrees. While the rotation shaft 540 rotates in the reverse direction, the tiles move along the length direction of the conveying strip 100 toward the second glaze pouring station 2100, so that glaze is poured on the tiles.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims

1. A glazed tile glazing line comprising a pair of conveyor strips (100) for transporting tiles, characterized in that: the automatic tile pouring device is characterized by further comprising a first pouring glaze table (200) and a second pouring glaze table (2100) which are sequentially used for pouring glaze towards tiles on the conveying strip (100), and a turning device which is arranged between the first pouring glaze table (200) and the second pouring glaze table (2100) and used for turning the front side and the back side of the tiles.

2. A glazed tile glazing production line as claimed in claim 1, wherein: turning device rises or the lifting unit (400) that descends including clamping component (300), control clamping component (300) that are used for pressing from both sides tight tile both ends and is used for controlling clamping component (300) to drive runner assembly (500) that the tile overturns, clamping component (300) including the symmetry set up at die clamping cylinder (310) at tile both ends, support tight pole (320) and be used for supporting support post (410) of die clamping cylinder (310), die clamping cylinder (310) level sets up, and its piston rod towards the tile tip setting and with support tight pole (320) fixed connection, support post (410) vertical setting and its one end are connected with lifting unit (400), and the other end rotates with the cylinder body of die clamping cylinder (310) to be connected, and runner assembly (500) are connected with die clamping cylinder (310).

3. A glazed tile glazing production line as claimed in claim 2, wherein: the lifting assembly (400) comprises a lifting hydraulic cylinder (420) and a supporting cross rod (430), the supporting cross rod (430) is horizontally arranged below the conveying strip (100), the lifting hydraulic cylinder (420) is vertically arranged, a piston rod of the lifting hydraulic cylinder is fixedly connected with the supporting cross rod (430), and the supporting upright column (410) is fixedly connected with the supporting cross rod (430).

4. A glazed tile glazing production line as claimed in claim 3, wherein: the rotary component (500) is provided with a pair of sliding rail columns (510), a rotary gear (520) and a lifting rack (530), the sliding rail columns (510) are vertically arranged, sliding chutes (511) are formed in the sliding rail columns (510) from the upper ends to the lower ends along the length direction of the sliding rail columns, the lifting rack (530) slides in the sliding chutes (511) along the vertical direction, the rotary gear (520) is meshed with the lifting rack (530), a rotary shaft (540) is fixedly connected with the rotary gear (520) through a coaxial key, one end of the rotary shaft (540) penetrates through the supporting upright column (410) and is fixedly connected with a cylinder body of the clamping cylinder (310), a friction plate (550) used for increasing friction force between the clamping cylinder (310) and the supporting upright column (410) is arranged between the clamping cylinder (310) and the supporting upright column (410), and the lower ends of the sliding rail columns (510) are fixedly connected with a base surface, the upper end is connected with a propping piece used for propping the lifting rack (530) to move upwards.

5. A glazed tile glazing production line as claimed in claim 4, wherein: sliding slot (512) have been seted up along its length direction in slide rail post (510), the piece of propping is including sliding the pegboard (570) of pegging graft in sliding slot (512) inside and with pegboard (570) upper end fixed connection prop tight board (560), prop tight board (560) and be located the top of sliding slot (512) and spout (511), and pegboard (570) are connected with the fixed part of its position that is located sliding slot (512) inside.

6. A glazed tile glazing production line as claimed in claim 5, wherein: the fixing piece is a fixing bolt, the fixing bolt is in threaded connection with the side wall of the sliding slot (512), and one end of the fixing bolt penetrates through the inside of the sliding slot (512) and abuts against the insertion plate (570).

7. A glazed tile glazing production line as claimed in claim 6, wherein: the turnover device further comprises a micro-baking assembly (600) used for pre-drying the tiles, wherein the micro-baking assembly (600) comprises an oven shell (610), a heating wire (620) arranged inside the oven shell (610) and supporting legs (630) used for supporting the oven shell (610), the oven shell (610) is sleeved on the outer side of the conveying strip (100), and the oven shell (610) is located between the lifting assembly (400) and the first glazing table (200).

8. A glazed tile glazing production line as claimed in claim 1, wherein: the structure of first glaze pouring table (200) and second glaze pouring table (2100) is the same, first glaze pouring table (200) including glaze pouring frame (210) and supply glaze subassembly (230), glaze pouring frame (210) along perpendicular to conveying strip (100) traffic direction reciprocating sliding connection have be used for towards tile spray glaze spray nozzle (220), spray nozzle (220) are located the tile top, and spray nozzle (220) one end sets up towards the tile, and the other end is connected with and supplies glaze subassembly (230), spray nozzle (220) are connected with its reciprocating motion's of drive subassembly.

9. A glazed tile glazing production line as claimed in claim 8, wherein: the glaze supply assembly (230) comprises a glaze supply hose (231), a glaze supply pump (232) and a glaze barrel (233) for storing glaze, one end of the glaze supply hose (231) is connected with the spray nozzle (220), the other end of the glaze supply hose is connected with the glaze supply pump (232), the glaze supply pump (232) is placed in the glaze barrel (233), the glaze pouring frame (210) is fixedly connected with a support slide rod (240), the support slide rod (240) is horizontally and vertically arranged on the conveying strip (100), the driving assembly comprises a turntable (269), a push rod (271) and a slide rod (250) which is slidably connected with the support slide rod (240), the slide rod (250) is slidably arranged on the support slide rod (240) along the length direction of the support slide rod (240), the spray nozzle (220) is fixedly connected with the slide rod (250), the plate surface of the turntable (269) is vertically arranged, and the turntable (269) and the glaze pouring frame (210) are rotatably arranged, the lateral wall fixedly connected with connecting rod (270) of carousel (269), connecting rod (270) are parallel to the quotation setting of carousel (269) along its length direction, and connecting rod (270) do not pass through the central axis of carousel (269) along its length direction's extension line, catch bar (271) one end rotates with connecting rod (270) and sets up, and the other end articulates with slide bar (250) and sets up, carousel (269) are connected with the drive it and carry out pivoted power component (280).

10. A glazed tile glazing production line as claimed in claim 9, wherein: power component (280) include power motor (281) and connect belt (282), and carousel (269) deviates from coaxial fixedly connected with connecting axle (283) of face of connecting rod (270), connecting axle (283) with water glaze frame (210) and rotate and be connected, the coaxial fixed cover of connecting axle (283) is equipped with and rotates band pulley (285), power motor (281) with water glaze frame (210) fixed connection, and the output shaft coaxial key fixedly connected with driving pulley (284) of power motor (281), connect belt (282) cover and establish on rotating band pulley (285) and driving pulley (284).